Emergency Power System for Blowout Preventer of a Petroleum Apparatus

ABSTRACT

An improved emergency power system is disclosed for providing electrical power to a load such as a blowout preventer of a petroleum drilling apparatus. The improved emergency power system comprises a thermal battery having an anode and a cathode with a separator containing an electrolyte disposed therebetween. An internal heat layer is located in proximity to the separator containing the electrolyte. A squib is provided for activating the internal heat layer. The thermal battery remains dormant until the squib is energized to ignite the squib enabling the heat layer to render the electrolyte molten thereby activating battery to provide electrical power to the load. The squib may be energized remotely, mechanically or electrically.

CROSS-REFERENCE TO RELATED APPLICATIONS

This application claims benefit of U.S. Patent Provisional applicationNo. 61/404,629 filed Oct. 6, 2010. All subject matter set forth inprovisional application No. 61/404,629 filed Oct. 6, 2010 is herebyincorporated by reference into the present application as if fully setforth herein.

BACKGROUND OF THE INVENTION

1. Field of the Invention

This invention relates to thermal batteries and more specifically to athermal battery for providing standby or emergency power for a load suchas a conventional blowout preventer of a petroleum drilling operation

2. Description of the Related Art

The drilling for oil has always been a hazardous activity for thepersonnel at the well site, the drilling equipment, and the environment.The uncontrolled release of crude oil and/or natural gas after failureof pressure control systems is known as a blowout. Prior to theinvention of pressure control equipment in the early 20^(th) century, anuncontrolled release of crude oil was known as a gusher.

In 1924, the first successful blowout preventer (BOP) was invented. Astechnology improved, blowouts became relatively rare. Modern blowoutpreventers comprise a blowout preventer stack, including several blowoutpreventers of varying type and function and auxiliary components.Blowout preventers are used on surface as wells subsea well includingdeepwater wells.

A typical sub-sea blowout preventer would include a stack of blowoutpreventers and associated hydraulic and electrical systems andcomponents. Control of the blowout preventer is typically accomplishedin one of four ways. A first way of controlling a blowout preventer isby an electrical control signal from the surface via a control cable. Asecond way of controlling a blowout preventer is by an acousticalcontrol signal sent from the surface based acoustic signal generatorthrough the water to the blowout preventer. A third way of controlling ablowout preventer is by a remotely operated vehicle (ROV) mechanicallyoperating a control valve to provide hydraulic pressure to the blowoutpreventer. A forth way of controlling a blowout preventer is by a“dead-man” switch for fail-safe activation in the event of loss ofcontrol and power as well as loss of hydraulic lines.

Generally, two control pods are provided for redundant operation. Theprimary control of the pods is electrical, while acoustical controls,ROV controls and dead-man controls are secondary. An emergencydisconnect system (EDS) is designed to disconnect the rig from the wellin the event of an emergency. The EDS also triggers the dead-man switchwhich closes the blowout preventer.

Although blowouts are now rather rare, both the short and long termeffects of a sub-sea blowout can be catastrophic. The Deepwater Horizonblowout graphically illustrates the need to further refine blowoutpreventers and the associated components to achieve total reliability.In the case of the Deepwater Horizon, a document discussed in theCongressional hearings suggested that a battery in the blowoutpreventers control pod had failed. Several other scenarios have alsobeen proposed to explain the failure of the blowout preventers.

There have been many in the prior art who have attempted to solve theseproblems with varying degrees of success. None, however, completelysatisfies the requirements for a complete solution to the aforesaidproblems. The following U.S. Patents are attempts of the prior art tosolve this problem.

U.S. Pat. No. 3,695,349 to Murman, et al discloses the constriction of apacker or other tool about a pipe string being run in a well altered insuch manner while a pipe joint is passing through the packer as tofacilitate rapid running of the string in a well and to reduce wear ofthe packer.

U.S. Pat. No. 4,215,746 to Hallden, et al discloses an electro-pneumaticor electro-hydraulic safety system for shutting in a well or the like inthe event of unusual pressure conditions in the production line of thewell. The safety system includes a pressure transducer which senses theflow line pressure and provides a corresponding electrical signal to adigital controller. When the signal applied to the controller is outsideof a preset range defined between low and high settings of thecontroller, a control circuit de-energizes a solenoid valve which bleedsfluid from a fluid actuator in order to close a surface safety valve.Once the safety valve has closed, the controller is latched out ofservice and must be manually reset before the safety valve can beopened. For protection of a subsurface safety valve, the safety systemprovides a time delay between opening of the subsurface valve andopening of the surface valve and also between closing of the surfacevalve and closing of the subsurface valve.

U.S. Pat. No. 4,317,557 to Orr discloses a blowout preventer controlsystem for use in well operations including a blowout preventer havingat least one opening chamber and at least one closing chamber, and anoperating power fluid source connected to the blowout preventer openingand closing chambers by an opening conduit and a closing conduit,respectively. A valve controlled conduit is connected to the openingconduit to ensure drainage of power fluid from the opening chamber ofthe blowout preventer. A three-way shuttle valve is connected into theclosing conduit close to the blowout preventer. The shuttle valve isprovided with an inlet which is connected to the closing conduit andanother inlet which is connected by a conduit to an independent blowoutpreventer operating power fluid source. An outlet of the shuttle valveis connected to the closing chamber of the blowout preventer.

U.S. Pat. No. 4,337,653 to Chauffe discloses a control and recordersystem for a blowout preventer for providing a record of operation andstatus of the various components of the blowout control system atperiodic times and after a function operation. The system monitorsvarious functions such as whether the accumulator pump is running, theopen and close status of the various rams, bypass, annular, flow line,kill line and choke line as well as various pressures, such as in theannular, the accumulator and the manifold, flow measurements of variousfluids in the system and provides alarms for various parameter values.Control and status information may be transmitted through . fiber opticcables between various control stations at the rig floor, accumulatorsand remote locations for avoiding interference by electrical noises orradio frequencies and providing a safety link through hazardous gasareas.

U.S. Pat. No. 4,349,041 to Bates discloses a control valve system andmethod for blowout preventers having an actuating piston for actuatingthe closing of the blowout preventer whereby the piston has an openingside and a closing side. The control valve system and method include ameans for selectively directing fluid from the opening side of theactuating piston to the closing side of the actuating piston in order toreduce the fluid requirements for closing the blowout preventer and thereduction in stalled horsepower requirements thereby.

U.S. Pat. No. 4,384,612 to Bradford, et al discloses a control apparatusfor preventing inadvertent operation of the draw works of a drilling rigupon closure of an associated blowout preventer, the draw works being atleast partially operated by air from an air source connected thereto byan air conduit. The control apparatus may comprise control componentsfor connection to the air conduit and movable from a first mode, inwhich air is permitted to communicate with the draw works through theair conduit, and a second mode, in which air is prevented fromcommunicating with the draw works. Also included are monitor componentsfor connection to the blowout preventer and the control components forsensing whether the blowout preventer is in opened or closed positionsand initiating movement of the control components to the second modeupon movement of the blowout preventer to the closed position.

U.S. Pat. No. 4,422,503 to Goans discloses an improved control line blowout preventer valve, having a fluid pressure chamber interposed in acontrol line extending from a surface control panel to a down-holesafety valve in a subterranean well. Axially spaced inlet and outletopenings are provided in the pressure chamber and a piston isreciprocally mounted between the inlet and outlet openings. A sealingplug carried by the piston cooperates with a seal surrounding the inletopening. A bypass passage through the piston mounts a check valve whichpermits free fluid flow in the direction from the control panel to thesubsurface safety valve but only a restricted fluid flow in the oppositedirection. A check valve is mounted in the outlet passage to preventfluid flow from the subsurface safety valve to the control panel. Afusible link normally maintains this check valve off its seat so that itdoes not close until the occurrence of an elevated temperature caused byfire. At the inlet port a bleed valve which is thermally activated isincorporated in order to bleed off the safety valve, or other apparatus,pressure in the event of a fire.

U.S. Pat. No. 5,070,904 to McMahon, Jr., et al discloses a blowoutpreventer sub-sea control system utilizing hydraulic control ofnon-critical functions and electro-hydraulic control of selectedcritical functions, such as the closing mode of one or more shear ramblowout preventers, one or more pipe ram blowout preventers and one ormore annular type blowout preventers. In an alternative embodiment, theuse of a conductive fluid in a hydraulic hose enables electric signalsand hydraulic signals to be transmitted in the same hose.

U.S. Pat. No. 5,398,761 to Reynolds, et al discloses a modular sub-seacontrol pod assembly having a retrievable pod assembly and a receptacleassembly. The retrievable pod assembly has a stab block and at least onefunction port having an opening in the stab block. The retrievable podassembly includes a pod gate which is adapted to move between a firstposition in which the pod gate covers the function port opening and asecond position in which the pod gate does not cover the function portopening. The receptacle assembly includes a receptacle base moduleadapted to receive the stab block and a receptacle function port adaptedto be connected to a blowout preventer hydraulic operator. Thereceptacle assembly includes a receptacle gate which is adapted to movebetween a first position in which the receptacle gate covers thereceptacle function port opening and a second position in which thereceptacle gate does not cover the receptacle function port opening.Seal assemblies are provided to operate with the pod gates and thereceptacle gates to seal the function and receptacle function portsagainst the intrusion of saltwater.

U.S. Pat. No. 6,367,566 to Hill discloses a system and method of thepresent invention permitting control of down hole fluid pressures duringunder balanced drilling, tripping of the drill string, and wellcompletion to substantially avoid “killing” of the well and therebydamaging the producing formations in the well bore. The system andmethod utilizes separate and interconnected fluid pathways forintroducing a downwardly flowing hydrodynamic control fluid through onefluid pathway and for removing through the other fluid pathway acommingled fluid formed by mixing of the hydrodynamic control fluid andthe well bore fluids flowing upwardly in the well bore.

U.S. Pat. No. 7,062,960 to Couren, et al discloses that the consequencesof any failure of a blow out preventer assembly to operate correctly inan emergency can be far reaching. Thus, there is provided an apparatusfor registering parameters in the bore of a member which is, in use,connected to a pressurized housing, the apparatus comprising: anelectro-control package for attachment, in use, to the member; a testassembly placed, in use, in the member; the electro-control package andthe test assembly having means for sending signals to and receivingsignals from one another.

U.S. Pat. No. 7,222,674 to Reynolds discloses a distributed functioncontrol module adapted for use in a modular blowout preventer stack foruse sub-sea comprising a housing, adapted to be manipulated by aremotely operated vehicle (ROV) with a stab portion adapted to bereceived into a blowout preventer stack control module receiver. Controlelectronics, adapted to control a predetermined function with respect tothe blowout preventer stack are disposed within the housing andconnected to one or more controllable devices by a wet mateableconnector interface.

Others in the prior art have provided rechargeable batteries foremergency power applications for a variety of electronic equipment.Unfortunately, typical rechargeable batteries do not have an extendedshelf life.

Thermal batteries have been used in the past for power sources in manymilitary applications. Thermal batteries are mission critical powersources used extensively for strategic and tactical Department ofDefense applications. As such, the reliability of thermal batteries isthe highest available for portable power generation sources. Thermalbatteries have no self-discharge reactions, and can be activated at anytemperature extreme needed (typical test conditions are −54 to +60° C.but can be as high as +80° C.). Thermal batteries also offer extremelyhigh current load capabilities and can be custom fabricated to supportany voltage and current requirement. The shelf-life of thermal batteriesis over 30 years. Typically a thermal battery outlives the systemutilizing the thermal battery.

Therefore, it is an object of the present invention to provide animproved emergency power system incorporating a thermal battery forproviding primary or backup emergency power.

Another object of this invention is to provide an improved emergencypower system incorporating a single use thermal battery.

Another object of this invention is to provide an improved emergencypower system for use in a blowout preventer.

Another object of this invention is to provide an improved emergencypower system for extending the useful life of blowout preventer controlsystems.

Another object of this invention is to provide an improved emergencypower system incorporating a thermal battery that may be activated by acontrol cable.

Another object of this invention is to provide an improved emergencypower system incorporating a thermal battery that is activated by anacoustical control signal.

Another object of this invention is to provide an improved emergencypower system incorporating a super-capacitor or small rechargeablebattery for receiving an acoustical control signal to activate theimproved emergency power system.

Another object of this invention is to provide an improved emergencypower system incorporating a thermal battery that may be activated by amanipulator arm on a remotely operated vehicle (ROV).

The foregoing has outlined some of the more pertinent objects of thepresent invention. These objects should be construed as being merelyillustrative of some of the more prominent features and applications ofthe invention. Many other beneficial results can be obtained bymodifying the invention within the scope of the invention. Accordinglyother objects in a full understanding of the invention may be had byreferring to the summary of the invention, the detailed descriptiondescribing the preferred embodiment in addition to the scope of theinvention defined by the claims taken in conjunction with theaccompanying drawings.

SUMMARY OF THE INVENTION

The present invention is defined by the appended claims with specificembodiments being shown in the attached drawings. For the purpose ofsummarizing the invention, the invention relates to an improvedemergency power system for providing electrical power to a load,comprising a thermal battery having an anode and a cathode with aseparator containing an electrolyte disposed between the anode and thecathode. An internal heat layer is located in proximity to the separatorcontaining the electrolyte. A squib has a first and a second squibterminal located proximate the internal heat layer. An anode and acathode connector connect the anode and cathode to the load. A remotelyoperated actuator energizes the squib for igniting the squib and theheat layer to activate the electrolyte to provide electrical power tothe load.

The improved emergency power system is suitable for use as a primary ora secondary power source for a blowout preventer of a petroleumapparatus. In one specific example of the invention, the remotelyoperated actuator is operated from a remote location. In anotherspecific example of the invention, the remotely operated actuatorcomprises an electrical connection to a remote electrical source. In afurther example, the remotely operated actuator comprises an acousticalconnection to a remote acoustical source. In still a further example,the remotely operated actuator comprises direct mechanical contact witha remote operated vehicle.

In another embodiment, the invention is incorporated into an improvedemergency power system for providing electrical power to a loadcomprising a thermal battery having a primer for activating the thermalbattery. An actuator comprises a spring-loaded firing pin aligned withthe primer. A blocking member maintains the spring-loaded firing pin ina cocked position. The spring-loaded firing pin impacts the primer uponremoval of the blocking member to ignite the primer and the heat layerto activate the electrolyte to provide electrical power to the load.

In another embodiment, the invention is incorporated into an improvedemergency power system for providing electrical power to a loadcomprising a thermal battery having a squib. A sensor provides a sensoroutput upon sensing a requirement of electrical power to the load. Aremotely operated actuator is connected to the sensor for energizing thesquib for igniting the squib and the heat layer to activate theelectrolyte to provide electrical power to the load. In one example, thesensor provides a sensor output upon sensing different and undesirablepressure in a petroleum apparatus.

In still another embodiment, the invention is incorporated into animproved emergency power system for providing secondary electrical powerto a primary battery for a blowout preventer of a petroleum apparatus.The primary battery is connected to an electric motor for drivinghydraulic apparatus to operate the blowout preventer. An isolator isinterposed between the primary battery electrical power and the electricmotor of the blowout preventer. A thermal battery is connected to theisolator. An actuator actuates the thermal battery to provide electricalpower to the isolator upon failure of the primary battery. The isolatorprevents electrical current from flowing from the thermal battery intothe primary battery.

In an alternate example, a sensor senses an undesired pressure in thepetroleum apparatus and senses the failure of the primary battery. Thesensor is connected to the actuator for actuating the thermal batteryupon sensing an undesired pressure in the petroleum apparatus and thefailure of the primary battery.

The foregoing has outlined rather broadly the more pertinent andimportant features of the present invention in order that the detaileddescription that follows may be better understood so that the presentcontribution to the art can be more fully appreciated. Additionalfeatures of the invention will be described hereinafter which form thesubject of the claims of the invention. It should be appreciated bythose skilled in the art that the conception and the specificembodiments disclosed may be readily utilized as a basis for modifyingor designing other structures for carrying out the same purposes of thepresent invention. It should also be realized by those skilled in theart that such equivalent constructions do not depart from the spirit andscope of the invention as set forth in the appended claims.

BRIEF DESCRIPTION OF THE DRAWINGS

For a fuller understanding of the nature and objects of the invention,reference should be made to the following detailed description taken inconnection with the accompanying drawings in which:

FIG. 1 is a side section view of thermal battery incorporating thepresent invention;

FIG. 2 is an isometric view of a blowout preventer of the prior art;

FIG. 3 is a block diagram of the prior art electrical components of theblowout preventer of FIG. 2.

FIG. 4 is a block diagram similar to FIG. 3 incorporating the improvedthermal battery of the present invention;

FIG. 5 is a magnified view of the conventional actuator of FIG. 3;

FIG. 6 is a magnified view of the thermal battery actuator of FIG. 4;

FIG. 7 is a block diagram of the thermal battery of the presentinvention connected as a secondary power source;

FIG. 8 is a magnified view of the isolator of FIG. 7;

FIG. 9 is a side view of an example of a mechanical device for actuatingthe thermal battery shown in a cocked position; and

FIG. 10 is a view similar to FIG. 9 with the mechanical device shown ina firing position.

Similar reference characters refer to similar parts throughout theseveral Figures of the drawings.

DETAILED DISCUSSION

FIG. 1 is a side section view of thermal battery 10 suitable for usewith the present invention. The thermal battery 10 comprises a pluralityof cells 20 shown as cell 21-23 arranged in a stacked relationship. Eachof the cells 21-23 comprises a plurality of battery components shown asan anode 31, a cathode 32, a separator 33 and a heat source 34. Each ofthe anode 31, cathode 32, separator 33 and heat source 34 is providewith holes 35-38, respectively.

The plurality of cells 20 are enclosed in a battery case 40. The batterycase supports battery terminals 41 and 42. Insulation 44 is interposedbetween the battery case 40 and the plurality of cells 20. The pluralityof cells 20 are connected to the battery terminals 41 and 42 byconductors 47 and 48.

The thermal battery 10 is provided with a squib 50 having a first and asecond electrical terminal 51 and 52. The first and second electricalterminals 51 and 52 are connected to squib leads 54 and 55 locatedadjacent to the battery terminals 41 and 42.

Upon the application of electric voltage to the squib terminals 51 and52, the squib 50 ignites each of the heat layers 34 within the cells21-23. The ignition of the heat layers 34 within the cells 21-23activates the electrolyte within the separators 33 to actuate each ofthe cells 20 within the battery case. Voltage produced by each of theplurality of cells 20 appears at the battery terminals 41 and 42.

FIG. 2 is an isometric view of a blowout preventer 60 incorporating theimproved thermal battery 10 of FIG. 1. In this example, the blowoutpreventer 60 is shown located adjacent to the seafloor 62 andinterconnected between a wellhead 64 and a riser 66. The connection ofthe blowout preventer 60 to the wellhead 64 and the riser 66 should bewell known to those skilled in the art.

The blowout preventer 60 comprises a housing 70 having a tubular boreprotector 72 located within the housing 70. The tubular bore protector72 interconnects the wellhead 64 and the riser 66. The bore protector 72is formed from a malleable material capable of deformation forterminating communication between the wellhead 64 and the riser 66 asshould be well known to those skilled in the art.

A first and a second shearing ram 81 and 82 are positioned transverse tothe bore protector 72. The first and second shearing rams 81 and 82 areoperated by a first and a second hydraulic cylinder 83 and 84,respectively.

An electric motor 90 operates a hydraulic pump 92 to provide hydraulicfluid pressure to the hydraulic cylinders 83 and 84. A sensor 96 islocated in the wellhead 64 for providing an output upon sensing apotential blowout from the wellhead 64. Preferably, the sensor 96 is apressure sensor.

A control 100 is provided for controlling the operation of the blowoutpreventer 60. The control 100 is interconnected between the electricmotor 90 and a conventional battery 110. In the event the sensor 96senses an increase in pressure indicative of an imminent blowout fromthe wellhead 64, the sensor 96 provides an output to the control 100.The control 100 directs electrical power from the conventional battery110 to the electric motor 90 to rotate hydraulic pump 92 to providehydraulic pressure to the first and second shearing rams 81 and 82. Thefirst and second shearing rams 81 and 82 deform and seal the tubularbore protector 72 to prevent a blowout from the wellhead 64.

FIG. 3 is a block diagram of the prior art electrical components of theblowout preventer of FIG. 2. The conventional battery control 100 isconnected to the electric motor 90 by conductors 101 and 102. Theconventional battery 110 includes battery terminals 111 and 112 forproviding electrical power to the conventional battery control 100. Aconventional actuator 120 actuates the conventional battery control 100to direct electric power from the conventional battery 110 to theelectric motor 90. The conventional actuator 120 will be described ingreater detail with reference to FIG. 5.

It should be readily appreciated by those skilled in the art that afailure of the conventional battery 110 renders inoperative theelectrical operation of the blowout preventer 60. In such a case, theonly solution is to provide external electric power to the electricmotor 90 to provide external hydraulic power to the hydraulic motor 92for operating the first and second shearing rams 81 and 82 to deform andseal the bore protector 72 to prevent a blowout from the wellhead 64.

FIG. 4 is a block diagram similar to FIG. 3 illustrating the presentinvention incorporating the improved thermal battery 10 shown in FIG. 1.In this embodiment, the thermal battery 10 is incorporated as theprimary power source for the blowout preventer 60. In contrast to FIG.3, the terminals 41 and 42 of the thermal battery 10 are connecteddirectly to the motor 90. A thermal battery actuator 130 is connected tothe first and second electrical terminals 51 and 52 of the squib 50shown in FIG. 1. The thermal battery actuator 130 will be described ingreater detail with reference to FIG. 6.

Insulation 15 encases the thermal battery 10 for maintaining a properoperational temperature of the thermal battery 10 in the event thethermal battery 10 is located in a cold environment such as a freezingsurface environment or a deep-sea well.

In contrast to the conventional battery 110 of FIG. 3, the thermalbattery 10 can remain dormant for decades without any loss of electricalpower. The separators 33 containing the electrolyte are inert prior toactivation of the thermal battery 10. When the thermal battery actuator130 energizes the squib 50 shown in FIG. 1, the squib ignites the heatlayer layers 34 to activate the electrolyte to provide electrical powerto the electric motor 90 to provide external hydraulic power to thehydraulic motor 92 for operating the first and second shearing rams 81and 82 to deform and seal the bore protector 72 to prevent a blowoutfrom the wellhead 64. The shelf life and reliability of the thermalbattery 10 provide superior performance over the conventional battery110 of the prior art.

FIG. 5 is a magnified view of the conventional actuator 120 of FIG. 3.The conventional actuator 120 includes the various devices for actuatinga blowout preventer 60. The first device for actuating a blowoutpreventer 60 includes a remote control cable extending from a signalgenerator (not shown) located remote from the blowout preventer 60. Thesecond device for actuating a blowout preventer 60 includes a remoteacoustical signal generated from an acoustical signal generator (notshown) located remote from the blowout preventer 60 and a localacoustical receiver (not shown).

The third device for actuating a blowout preventer 60 includes a localsensor such as sensor 96 generating a signal from the wellhead 64. Thefourth device for actuating a blowout preventer 60 is through a remotelyoperated vehicle (not shown) located adjacent to the blowout preventer60.

All of the various devices for actuating the blowout preventer 60 shownin the conventional actuator 130 are dependent upon electrical powerfrom the conventional battery 110. Failure of the conventional battery110 results in failure of the conventional actuator 130.

FIG. 6 is a magnified view of the thermal battery actuator 130 of FIG.4. The thermal battery actuator 130 includes the various devices foractuating a blowout preventer 60. The first device for actuating ablowout preventer 60 includes a remote control cable extending from asignal generator (not shown) located remote from the blowout preventer60. The second device for actuating a blowout preventer 60 includes aremote acoustical signal generated from an acoustical signal generator(not shown) located remote from the blowout preventer 60 and a localacoustical receiver (not shown).

The third device for actuating a blowout preventer 60 includes a localsensor such as sensor 96 generating a signal from the wellhead 64. Thefourth device for actuating a blowout preventer 60 is through a remotelyoperated vehicle (not shown) located adjacent to the blowout preventer60.

The remote acoustical signal (second device) and the local sensor (thirddevice) are dependent upon an internal battery 140 for powering thethermal battery actuator 130. In contrast to the conventional actuator120, the internal battery 140 powers only the equipment required toenergize the squib 50 to activate the thermal battery 10. The internalbattery 140 is not required to power the electric motor 90 as theconventional battery 110 in FIGS. 3 and 5.

In this example, the internal battery 140 is shown as a low powerbattery 142 and a super capacitor 144 connected in a parallelarrangement. The internal battery 140 is sufficient to power the localacoustical receiver (not shown) and the local sensor 96 for energizingthe squib 50. Once the squib 50 is energized, the thermal battery 10powers the electric motor 90.

The thermal battery actuator 130 also includes a mechanical device suchas a direct mechanical contact for activating the thermal battery 10. Anexample of the mechanical device will be fully explained with referenceto FIG. 9.

FIG. 7 is a block diagram of the thermal battery 10 of the presentinvention connected as a secondary power source. The conventionalbattery 110 provides primary electrical power through a positive and anegative terminal 111 and 112 to the conventional battery control 100.The conventional battery control 100 applies the electrical power fromthe conventional battery 110 through connectors 101 and 102 upon asignal from a primary actuator 120. The electrical power from theconnectors 101 and 102 of the conventional battery 110 is applied to anisolator 150.

The thermal battery 10 is used as a secondary electrical power sourcefor the blowout preventer 60. The terminals 41 and 42 of the thermalbattery 10 are connected to the isolator 150. The isolator 150 preventselectrical current from flowing from the thermal battery 10 into theprimary battery 110 as will be described in greater detail withreference to FIG. 8.

A sensor 160 is connected to the secondary actuator 130 by connectors161 and 162. The sensor 160 includes the pressure sensor 96 for sensingan undesired pressure in the petroleum apparatus. In addition, thesensor 160 includes a primary battery sensor 164 for sensing the failureof the primary conventional battery 110.

The thermal battery 10 remains dormant during the normal operation ofthe primary battery 110. The sensor 160 provides an output to thesecondary actuator 130 for energizing the squib 50 to activate thethermal battery 10 upon an imminent blowout from the wellhead 64 such assensor 96 sensing an undesired pressure in the petroleum apparatus.

FIG. 8 is a magnified view of the isolator 150 of FIG. 7. The isolator150 in the simplest form comprises a single diode 170 interposed in theconnection between the positive terminal 111 of the conventional battery110 and the positive terminal 41 of the thermal battery 10 through theconventional battery control 100. The diode 170 prevents loading of thethermal battery 10 upon a failure of the conventional battery 110, theconventional battery control 100 and the primary actuator 120. Incontrast to many conventional isolators of the prior art, the isolator150 does not require a diode to prevent loading of the conventionalbattery 110 by the thermal battery 10 since the thermal battery 10presents a high impedance prior to activation.

FIG. 9 is a side view of an example of a mechanical device 180 foractuating the thermal battery 10. In one embodiment, the thermal battery10 is provided with a primer 57 for activating the heat source 34 withinthe thermal battery 10. The primer 57 provides an ignition to the heatlayer 34 upon a physical impact with the primer 57. The primer 57 may besimilar to a primer used any center fire cartridge.

One example of the mechanical device 180 comprises a cylinder 182defining a bore 184 with a firing pin disk 186 slidably mounted withinthe bore 184. A fixed disk 188 is secured within the bore 184 definingan aperture 189. A firing pin 190 is affixed to the firing pin disk 186for movement within the bore 184. A compression spring 192 urges thefiring pin 190 toward the primer 57. A blocking member 194 having a pullring 196 maintains the firing pin 182 in a cocked position to form aspring-loaded firing pin as shown in FIG. 9. The pull ring 196 may beprovided with a lanyard 198 for facilitating removal of the pull ring196.

FIG. 10 is a view similar to FIG. 9 with the mechanical device 180 shownin a firing position. Removal of the blocking member 194 by the pullring 196 enables the compression spring 192 to drive the firing pin 190into contact with the primer 57 to actuate the thermal battery 10. Thepull ring 196 may be removed by a remote operated vehicle (ROV)controlled from a remote location.

In the alternative, a pressure sensor in the form and a blowout plug(not shown) located at the position of sensor 96. The blowout plug (notshown) is affixed to the pull ring 196 by the lanyard 198. In the eventof excessive pressure within the wellhead 64, the blowout plug (notshown) will be expelled from the wellhead 64. The force of the blowoutplug (not shown) being expelled from the wellhead 64 removes the pullring 196 through the attached lanyard 198. This arrangement provides atotal mechanical failsafe activation of the blowout preventer 60 in theevent of excessive pressure within the wellhead 64.

The thermal battery 10 of the present invention may be used as a primarybattery or a secondary emergency backup battery. The thermal battery 10is capable of providing a large amount of power for a relatively shortduration. Benefits of a thermal battery include an approximate thirty(30) year shelf life with no maintenance. The thermal battery 10activates within deciseconds (tenths of a second) and has been tested toactivate between minus forty degrees centigrade to plus seventy degreescentigrade (−40° C. to +70° C.) with little to no adverse effects.Thermal batteries have been utilized in strategic and tactical weaponsystems and have a proven track record of “no fail” mission assurancefor many years.

The present disclosure includes that contained in the appended claims aswell as that of the foregoing description. Although this invention hasbeen described in its preferred form with a certain degree ofparticularity, it is understood that the present disclosure of thepreferred form has been made only by way of example and that numerouschanges in the details of construction and the combination andarrangement of parts may be resorted to without departing from thespirit and scope of the invention.

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 13. An improved emergency power system forproviding electrical power to actuate a blowout preventer of a petroleumapparatus, comprising; a thermal battery having an anode and a cathodewith a separator containing electrolyte disposed between said anode andcathode; an internal heater layer located in proximity to saidelectrolyte separator; a squib having a first and a second squibterminal located proximate said internal heater; an anode and a cathodeconnector connecting said anode and cathode to the blowout preventer;and a sensor for providing a sensor output upon sensing the undesiredpressure in the petroleum apparatus; an electrical actuator connected tosaid sensor for electrically igniting, said squib and said heater toactivate said electrolyte to provide electrical power to the blowoutpreventer; and a mechanical actuator connected to a primer formechanically igniting said squib and said heater to activate saidelectrolyte to provide electrical power to the blowout preventer. 14.(canceled)
 15. (canceled)
 16. An improved emergency power system as setforth in claim 13, wherein said mechanical actuator comprises a pullring for actuating said mechanical actuator upon movement of said pullring; and said pull ring adapted to be moved by a remote operatedvehicle (ROV) controlled from a remote location.
 17. An improvedemergency power system as set forth in claim 13, wherein said mechanicalactuator comprises a spring-loaded firing pin located adjacent to aprimer; a blocking member for maintaining said spring-loaded firing pinin a cocked position; and a mechanical removal of said blocking memberenabling said spring loaded tiring pin to impact said primer to actuatethe thermal battery.
 18. An improved emergency power system as set forthin claim 13, wherein said mechanical actuator comprises a pressuresensor in the form of a blowout plug; and a lanyard interconnecting saidblowout plug and said mechanical actuator for actuating said mechanicalactuator upon an excessive pressure within the wellhead expelling theblowout plug from the wellhead.
 19. An improved emergency power systemfor providing electrical power to actuate a blowout preventer of apetroleum apparatus, comprising; a thermal battery having an anode and acathode with a separator containing electrolyte disposed between saidanode and cathode; an internal heater layer located in proximity to saidelectrolyte separator; a squib having a first and a second squibterminal located proximate said internal heater; an anode and a cathodeconnector connecting said anode and cathode to the blowout preventer;and a sensor for providing a sensor output upon sensing the undesiredpressure in the petroleum apparatus; an actuator connected to saidsensor for electrically igniting said squib and said heater to activatesaid electrolyte to provide electrical power to the blowout preventer;and a mechanical device comprising a spring loaded firing pin and aprimer for mechanically igniting said squib and said heater to activatesaid electrolyte to provide electrical power to the blowout preventer.20. An improved emergency power system as set forth in claim 19, whereinsaid mechanical actuator comprises a pull ring for actuating saidmechanical actuator upon movement of said pull ring; and said pull ringadapted to be moved by a remote operated vehicle (ROV) controlled from aremote location.
 21. An improved emergency power system as set forth inclaim 19, wherein said mechanical actuator comprises a spring-loadedfiring pin located adjacent to a primer; a blocking member formaintaining said spring-loaded firing pin in a cocked position; and amechanical removal of said blocking member enabling said spring loadedfiring pin to impact said primer to actuate the thermal battery.
 22. Animproved emergency power system as set forth in claim 19, wherein saidmechanical actuator comprises a pressure sensor in the form and ablowout plug; and a lanyard interconnecting said blowout plug and saidmechanical actuator for actuating said mechanical actuator upon anexcessive pressure within the wellhead expelling the blowout plug fromthe wellhead.